CN204189571U - A kind of linked reactor for multi-level voltage source current converter - Google Patents
A kind of linked reactor for multi-level voltage source current converter Download PDFInfo
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- CN204189571U CN204189571U CN201420541788.2U CN201420541788U CN204189571U CN 204189571 U CN204189571 U CN 204189571U CN 201420541788 U CN201420541788 U CN 201420541788U CN 204189571 U CN204189571 U CN 204189571U
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- iron core
- shaped iron
- air gap
- insulated conductor
- stem
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Abstract
The utility model discloses a kind of linked reactor for multi-level voltage source current converter, comprise and there is left side stem stem, an E shaped iron core of right side stem stem and center pinch and the 2nd E shaped iron core respectively, a described E shaped iron core and the 2nd E shaped iron core relative spacing are placed, between leave a middle part air gap and two sidepiece air gaps, the length of middle part air gap is greater than sidepiece air gap; Also comprise the first insulated conductor circle and the second insulated conductor circle, first insulated conductor circle is wound around an E shaped iron core relative with the 2nd E shaped iron core two left side stem stems and coated sidepiece air gap on the left of this, and the second insulated conductor circle is wound around stem stems on the right side of an E shaped iron core two relative with the 2nd E shaped iron core and coated sidepiece air gap on the right side of this.Linked reactor for multi-level voltage source current converter of the present utility model, alleviates the impact on differential-mode current as far as possible when fully suppressing common mode current, thus realizes the reduction of converter bridge arm loss and improve the stability of capacitance voltage.
Description
Technical field
The utility model belongs to extraordinary power reactor field, is specifically related to a kind of linked reactor with iron core for multilevel converter.
Background technology
In the voltage source converter connecting electrical network, linked reactor plays effect induction reactance introduced between voltage source converter and electrical network.The introducing of induction reactance makes there is a buffer strip between voltage source converter and line voltage, thus can control its/reactive power of gaining merit exported to electrical network by the output voltage amplitude of regulation voltage source converter and phase place.
The critical piece of linked reactor is the coil that insulated conductor is made.Insulated conductor circle can be configured to the pattern of hollow body, is called air core reactor, also around the core FCl of magnetic material, can be called iron-core reactor.The connection reactance of voltage source converter adopts hollow reactance usually, and the feature of hollow reactance is that it can not produce saturated phenomenon, and inductance value is comparatively stable.
Figure 1 illustrates a kind of structure of multi-level voltage source current converter, multilevel converter is made up of six change of current brachium pontis A1 ~ A6, six brachium pontis are one group with two, as A1 and A4, A2 and A5, A3 and A6 connects, and is connected in series and is a little connected in a star fashion at two ends by transformer 5 incoming transport system 6, three groups of brachium pontis.Y-connection point forms positive pole (+Udc) and the negative pole (-Udc) of converter respectively.Brachium pontis is in series by the power model M1 ~ Mn of half-bridge pattern and reactor L, and reactor is wherein air core reactor.The alternating current (sense of current with reference in figure 1) that the electric current flow through in a facies unit has phase place identical, is called common mode current, also has the alternating current of phase 180 °, be called differential-mode current.
Wherein, differential-mode current flows directly into AC circuit, be that converter normally works necessary operating current, and common mode current forms flow cycle in three groups of facies units, usually can not flow into DC line and alternating current circuit.Common mode current does not affect for the normal work of converter, but common mode current flows through conductor, switching device and capacitor in converter bridge arm, can cause the problem such as loss increase and voltage fluctuation of capacitor aggravation of converter bridge arm.The core of reactor having E type to be combined with I shaped iron core on the market now, solution be the adjustment problem of size of gaps, and do not do the Curve guide impeller that elimination common mode current affects.
Utility model content
The purpose of this utility model is to overcome above-mentioned deficiency, provides one to have the inhibiting linked reactor of common mode current, solves the loss increase of converter bridge arm existence and the problem of voltage fluctuation of capacitor aggravation.
For reaching the object of above-mentioned utility model, the utility model is achieved through the following technical solutions:
A kind of linked reactor for multi-level voltage source current converter of the present utility model, comprise and there is left side stem stem, an E shaped iron core of right side stem stem and center pinch and the 2nd E shaped iron core respectively, a described E shaped iron core and the 2nd E shaped iron core relative spacing are placed, above-mentioned space interval between two left side stem stems and between two right side stem stems is as sidepiece air gap, space interval between Liang Ge center pinch is as middle part air gap, and the length of middle part air gap is greater than the length of sidepiece air gap; Also comprise the first insulated conductor circle and the second insulated conductor circle, first insulated conductor circle is wound around an E shaped iron core relative with the 2nd E shaped iron core two left side stem stems and sidepiece air gap between coated these two left side stem stems, and the second insulated conductor circle is wound around an E shaped iron core two the right side stem stems relative with the 2nd E shaped iron core and sidepiece air gap between coated these two right side stem stems.
The port of described first insulated conductor circle side and the second insulated conductor circle are connected two AC phase terminal of outside multilevel converter respectively at the port of same side, be electrically connected after the port of the respective opposite side of the first insulated conductor circle and the second insulated conductor circle connects altogether with the AC electric power system of outside.
Further, described middle part gas length is 3 times of sidepiece gas length.Because the length of middle part air gap is much larger than sidepiece air gap, therefore the magnetic resistance of middle part air gap is much larger than the magnetic resistance of sidepiece air gap, and principle can realize the inhibitory action to common mode current according to this.
Potting resin in an above-mentioned middle part air gap and two sidepiece air gaps.Resin can fill the inter-air space easily, and can keep stabilized structure and the electric property stability of iron core.
Compared with prior art, the utility model tool has the following advantages:
A kind of linked reactor for multi-level voltage source current converter of the present utility model, the significant difference of air gap and sidepiece air gap in the middle part of when it utilizes two E shaped iron cores to be oppositely arranged, the impact on differential-mode current can be alleviated when fully suppressing common mode current as far as possible, thus realize the reduction of converter bridge arm loss and improve the stability of capacitance voltage.
Accompanying drawing explanation
Fig. 1 is a kind of structure chart of multi-level voltage source current converter.
Fig. 2 is the structure chart of the linked reactor for multilevel converter of the present utility model.
Fig. 3 is the Application Example that linked reactor of the present utility model is connected with multilevel converter.
Fig. 4 be in linked reactor of the present utility model differential-mode current flow to schematic diagram.
Fig. 5 be in linked reactor of the present utility model common mode current flow to schematic diagram.
Embodiment
Embodiment
Be clearly and completely described the technical scheme in the utility model embodiment below in conjunction with drawings and Examples, obviously, described embodiment is only the utility model part embodiment, instead of whole embodiment.
Refer to Fig. 2, Fig. 2 is an embodiment of a kind of linked reactor for multi-level voltage source current converter of the present utility model, the linked reactor of this embodiment comprises an E shaped iron core 1, 2nd E shaped iron core 2, first insulated conductor circle 3 and the second insulated conductor circle 4, an above-mentioned E shaped iron core 1 have first on the left of stem stem 103, stem stem 102 and the first center pinch 101 on the right side of in the of first, wherein the first center pinch 101 be highly less than first on the left of stem stem 102 on the right side of stem stem 103 and first, 2nd E shaped iron core 2 have with second of E shaped iron core 1 same structure on the left of stem stem 203, stem stem 202 and the second center pinch 201 on the right side of in the of second.One E shaped iron core 1 and the 2nd E shaped iron core 2 staggered relatively, and on the left of in the of first on the left of stem stem 103 and second between stem stem 203, and on the right side of in the of first on the right side of stem stem 102 and second between stem stem 202, all leave sidepiece air gap G1; Middle part air gap G2 is then left between first center pinch 101 and the second center pinch 201.On an E shaped iron core of aforesaid way setting and the basis of the 2nd E shaped iron core, first insulated conductor circle 3 to be wound on the left of in the of first the coiling on stem stem 203 on the left of stem stem 103, second and coated respective side portion air gap G1, and the second insulated conductor circle 4 to be wound on the right side of in the of first the coiling on stem stem 202 on the right side of stem stem 102, second and coated respective side portion air gap G1.
Above-mentioned middle part air gap G2 length is 3 times of sidepiece air gap G1 length, and ensure that the length of sidepiece air gap G1 is more than or equal to critical length, this critical length is that reactor does not produce magnetically saturated length under accidental conditions simultaneously.
Please composition graphs 1 to Fig. 3 further, be convenient to clearlyer understand the concrete structure of the present embodiment and electrical principle.
The linked reactor of the present embodiment is applied in the multi-level voltage source current converter shown in Fig. 1, for group brachium pontis of in this multi-level voltage source current converter, linked reactor described in the utility model is replaced upper and lower two brachium pontis A1 in above-mentioned converter, two air core reactor L in A4, as shown in Figure 3, Fig. 3 is the Application Example that linked reactor of the present utility model is connected with multilevel converter, this converter at least has one group of upper and lower bridge arm, be respectively brachium pontis 701 and first time brachium pontis 702 on first, first insulated conductor circle 3 of the linked reactor of the present embodiment has port A and port B, second insulated conductor circle 4 has port C and port D, on port A and first wherein, brachium pontis 701 is electrically connected, port B and first time brachium pontis 702 is electrically connected, transformer 5 is electrically connected after port C is connected with port D, thus by transformer 5 by above-mentioned linked reactor and converter incoming transport system 6.
When coiling first insulated conductor circle 3 and the second insulated conductor circle 4, require to flow through successively the direct current forward current of A, C, D, B port or the sense of current of negative current in coil as shown in Figure 5, guarantee linked reactor of the present utility model correctly practices.
The utility model is based on the general principle in magnetic Circuit Design.As shown in Figure 4, the electric current flow through in two groups of coils is differential-mode current, and for the differential-mode current in the first insulated conductor circle 3, its inductance value flowed through is:
Wherein, N is the coil windings number of turn, Φ
3for from magnetic flux, Φ
43be the mutual flux of the second insulated conductor circle 4 to the first insulated conductor circle 3, R
1and R
2be respectively the magnetic resistance (ignoring iron core magnetic resistance) of sidepiece air gap G1 and middle part air gap G2, I
3Dand I
4Dbe respectively the differential-mode current flow through in the first insulated conductor circle 3 and the second insulated conductor circle 4.
As shown in Figure 5, for the common mode current in the first insulated conductor turn coil 3, its inductance value flowed through is:
Wherein, N is the coil windings number of turn, Φ
3for from magnetic flux, Φ
43be the mutual flux of the second insulated conductor circle 4 to the first insulated conductor circle 3, R
1and R
2be respectively the magnetic resistance (ignoring iron core magnetic resistance) of sidepiece air gap G1 and middle part air gap G2, I
3Cand I
4Cbe respectively the common mode current flow through in the first insulated conductor turn coil 3 and the second insulated conductor circle 4.
Because the length of middle part air gap G2 is much larger than sidepiece air gap G1, the therefore magnetic resistance R of middle part air gap G2
2much larger than the magnetic resistance R of sidepiece air gap
1.As can be seen from above formula (1), (2), for differential-mode current, the inductance value that its inductance value flowed through will flow through much smaller than common mode current.Therefore, the utility model can alleviate the impact on differential-mode current as far as possible when fully suppressing common mode current.
By the linked reactor for multi-level voltage source current converter of the present utility model, the significant difference of air gap and sidepiece air gap in the middle part of when it utilizes two E shaped iron cores to be oppositely arranged, can play and fully suppress common mode current and alleviate the effect on differential-mode current impact as far as possible, thus realize the reduction of converter bridge arm loss and improve the stability of capacitance voltage.
Above-described embodiment only in order to the utility model is described and and technical scheme described by unrestricted the utility model; Therefore, although this specification has been described in detail the utility model with reference to each above-mentioned embodiment, those of ordinary skill in the art should be appreciated that and still can modify to the utility model or equivalent replacement; And all do not depart from technical scheme and the improvement thereof of spirit and scope of the present utility model, it all should be encompassed in the middle of right of the present utility model.
Claims (4)
1. the linked reactor for multi-level voltage source current converter, it is characterized in that: comprise and there is left side stem stem, an E shaped iron core of right side stem stem and center pinch and the 2nd E shaped iron core respectively, a described E shaped iron core and the 2nd E shaped iron core relative spacing are placed, above-mentioned space interval between two left side stem stems and between two right side stem stems is as sidepiece air gap, space interval between Liang Ge center pinch is as middle part air gap, and the length of middle part air gap is greater than the length of sidepiece air gap; Also comprise the first insulated conductor circle and the second insulated conductor circle, first insulated conductor circle is wound around an E shaped iron core relative with the 2nd E shaped iron core two left side stem stems and sidepiece air gap between coated these two left side stem stems, and the second insulated conductor circle is wound around an E shaped iron core two the right side stem stems relative with the 2nd E shaped iron core and sidepiece air gap between coated these two right side stem stems.
2. the linked reactor for multi-level voltage source current converter according to claim 1, it is characterized in that: the port of described first insulated conductor circle side and the second insulated conductor circle are connected two terminals of outside multilevel converter AC phase place respectively at the port of same side, be electrically connected with the AC electric power system of outside after the port of the respective opposite side of the first insulated conductor circle and the second insulated conductor circle connects altogether.
3. the linked reactor for multi-level voltage source current converter according to claim 1, is characterized in that: described middle part gas length is 3 times of sidepiece gas length.
4. the linked reactor for multi-level voltage source current converter according to claim 1 or 3, is characterized in that: described one middle part air gap and two sidepiece air gaps in potting resin.
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CN201420541788.2U CN204189571U (en) | 2014-09-19 | 2014-09-19 | A kind of linked reactor for multi-level voltage source current converter |
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CN201420541788.2U CN204189571U (en) | 2014-09-19 | 2014-09-19 | A kind of linked reactor for multi-level voltage source current converter |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104319075A (en) * | 2014-09-19 | 2015-01-28 | 南方电网科学研究院有限责任公司 | Connecting reactor for multi-level voltage source transverter |
CN105826064A (en) * | 2016-05-20 | 2016-08-03 | 哈尔滨理工大学 | Adjustable reactor based on magnetic circuit conversion |
AT16897U1 (en) * | 2015-04-14 | 2020-11-15 | Tridonic Gmbh & Co Kg | Transformer and LLC converter for operating a lamp |
-
2014
- 2014-09-19 CN CN201420541788.2U patent/CN204189571U/en not_active Expired - Fee Related
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104319075A (en) * | 2014-09-19 | 2015-01-28 | 南方电网科学研究院有限责任公司 | Connecting reactor for multi-level voltage source transverter |
CN104319075B (en) * | 2014-09-19 | 2017-05-24 | 南方电网科学研究院有限责任公司 | Connecting reactor for multi-level voltage source transverter |
AT16897U1 (en) * | 2015-04-14 | 2020-11-15 | Tridonic Gmbh & Co Kg | Transformer and LLC converter for operating a lamp |
CN105826064A (en) * | 2016-05-20 | 2016-08-03 | 哈尔滨理工大学 | Adjustable reactor based on magnetic circuit conversion |
CN105826064B (en) * | 2016-05-20 | 2017-10-13 | 哈尔滨理工大学 | A kind of REgulatable reactor converted based on magnetic circuit |
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